Locating method and system

ABSTRACT

A method and system for locating a target object in a target scene. The method may include obtaining a depth image of the target scene. The depth image may include a plurality of pixels. The method may also include, for each of the plurality of pixels of the depth image, determining a first target coordinate under a target coordinate system. The method may further include generating a marking image according to the depth image and the first target coordinates of the plurality of pixels in the depth image. The marking image may represent potential target objects in the depth image. The method may also include determining a locating coordinate of the target object under the target coordinate system according to the marking image.

CROSS REFERENCE

This application is a continuation of U.S. application Ser. No.16/513,804 filed on Jul. 17, 2019, which is a continuation ofInternational Application No. PCT/CN2017/119391, filed on Dec. 28, 2017,which claims priority of Chinese Application No. 201710047787.0 filed onJan. 19, 2017. Each of the above-referenced applications is incorporatedherein by reference in their entireties.

TECHNICAL FIELD

The present disclosure generally relates to a technical field oflocating of a target object, and more particularly to a system andmethod for locating the target object according to images.

BACKGROUND

During the shooting of some scenes, sometimes it is needed to shoot akey object in a scene in close-up, which requires an accurate locatingof the key object. For example, in a scene such as a classroom or ameeting room, when a person stands up, it is usually needed to shoot thestand-up person in close-up, which requires an accurate locating of thestand-up person. As another example, when a person appears in arestricted area, shooting the person in close-up may also facilitate theidentification of the violated person, which may also require that theviolated person is accurately located.

In prior arts, a target is usually located through a feature pointidentification technique with a following flow: pre-acquiring featureparameters of feature points belonging to a particular target andstoring the same, and matching feature parameters of feature pointsbelonging to an object currently present in the scene with the storedfeature parameters. If the matching is successful, the objectsuccessfully matched is determined to be the target.

Apparently, in the aforementioned technique, a target object may beaccurately located only when pre-stored feature parameters includefeature parameters of the target object to be located, which may causean inflexible locating of the target object with a low locatingaccuracy.

SUMMARY

According to an aspect of the present disclosure, a locating system forlocating a target object in a target scene may include at least onelocating device. During operation, the at least one locating device maybe configured to obtain a depth image of the target scene, the depthimage including a plurality of pixels. The at least one locating devicemay also be configured to, for each of the plurality of pixels of thedepth image, determine a first target coordinate under a targetcoordinate system. The at least one locating device may further beconfigured to generate a marking image according to the depth image andthe first target coordinates of the plurality of pixels in the depthimage, and determine a locating coordinate of the target object underthe target coordinate system according to the marking image. The markingimage may represent potential target objects in the depth image.

In some embodiments, to generate the depth image, the at least onelocating device may be configured to receive first electronic signalsincluding a first image of the target scene taken by a first imagesensor, and receive second electronic signals including a second imageof the target scene taken by a second image sensor. The at least onelocating device may also be configured to, for each pixel in the firstimage, determine a horizontal parallax between the pixel of the firstimage and a corresponding pixel of the second image, and, according tothe horizontal parallax, assign a gray value to a corresponding pixel ofthe depth image.

In some embodiments, the locating system may also include the firstimage sensor and the second image sensor. The second image sensor may beat a predetermined distance from the first image sensor. The first imagesensor may be configured to obtain the first image of the target scene.The second image sensor may be configured to obtain the second image ofthe target scene simultaneously with the first image sensor. The firstimage may include a plurality of pixels one-to-one corresponding to aplurality of pixels in the second image.

In some embodiments, the first image sensor may be at least part of afirst camera in a binocular camera, and the second image sensor may beat least part of a second camera in the binocular camera.

In some embodiments, for each of the plurality of pixels in the depthimage, to determine the first target coordinate, the at least onelocating device may be configured to determine a sensor coordinate ofthe pixel under a sensor coordinate system with respect to the firstimage sensor according to a first image coordinate and the gray value ofthe pixel, and determine the first target coordinate according to thesensor coordinate of the pixel.

In some embodiments, the locating system may further comprise acontroller. The locating device may be further configured to transmitthird electronic signals including the locating coordinate to thecontroller. The controller, upon receiving the third electronic signals,may transmit a control signal to at least one of the first image sensoror the second image sensor, causing the at least one of the first imagesensor or the second image sensor to be focused or zoomed in towards thelocating coordinate.

In some embodiments, to generate the marking image according to thedepth image and the plurality of first target coordinates, the at leastone locating device may be configured to determine disrupting pixels inthe depth image, and determine a second target coordinate for each ofthe disrupting pixels. The at least one locating device may also beconfigured to: determine an interference range in the target sceneaccording to the second target coordinates and a target region in thetarget scene where the target object is predicted to appear, anddetermine an identification range in the target scene according to theinterference range and the target region. The identification range maynot overlap with the interference range. The at least one locatingdevice may further be configured to identify first target pixels havingthird target coordinates within the identification range in the depthimage, and generate the marking image according to the first targetpixels.

In some embodiments, the marking image may include second target pixelscorresponding to the first target pixels. The second target pixels mayhave first gray values, and other pixels in the marking image may havesecond gray values.

In some embodiments, to determine the locating coordinate of the targetobject according to the marking image, the at least one locating devicemay be configured to: determine a target connected component in themarking image; determine a locating point in the marking image accordingto the connected component; and determine the locating coordinateaccording to a second image coordinate of the locating point.

In some embodiments, to determine the target connected component in themarking image, the at least one locating device may be configured todetermine at least one connected component in the marking image, andidentify a connected component having a number of pixels greater than orequal to a preset threshold from the at least one connected component asthe target connected component.

According to another aspect of the present disclosure, a locating systemfor locating a target object in a target scene may include a locatingdevice. The locating device may include a depth image module, acoordinate determination module, a marking image module, and a locatingcoordinate determination module. The depth image module may beconfigured to obtain a depth image of the target scene. The depth imagemay include a plurality of pixels. For each of the plurality of pixelsof the depth image, the coordinate determination module may beconfigured to determine a first target coordinate under a targetcoordinate system. The marking image module may be configured togenerate a marking image according to the depth image and the firsttarget coordinates of the plurality of pixels in the depth image. Themarking image may represent potential target objects in the depth image.The locating coordinate determination module may be configured todetermine a locating coordinate of the target object under the targetcoordinate system according to the marking image.

In some embodiments, the depth image module may be configured to receivefirst electronic signals including a first image of the target scenetaken by a first image sensor, and receive second electronic signalsincluding a second image of the target scene taken by a second imagesensor. The depth image module may also be configured to, for each pixelin the first image, determine a horizontal parallax between the pixel ofthe first image and a corresponding pixel of the second image, and,according to the horizontal parallax, assign a gray value to acorresponding pixel of the depth image.

In some embodiments, the locating system may further include the firstimage sensor and the second image sensor. The second image sensor may beat a predetermined distance from the first image sensor. The first imagesensor may be configured to obtain the first image of the target scene,and the second image sensor may be configured to obtain the second imageof the target scene simultaneously with the first image sensor. Thefirst image includes a plurality of pixels one-to-one corresponding to aplurality of pixels in the second image.

In some embodiments, the first image sensor may be at least part of afirst camera in a binocular camera, and the second image sensor may beat least part of a second camera in the binocular camera.

In some embodiments, for each of the plurality of pixels in the depthimage, to determine the first target coordinate, the coordinatedetermination unit may be configured to determine a sensor coordinate ofthe pixel under a sensor coordinate system with respect to the firstimage sensor according to a first image coordinate and the gray value ofthe pixel, and determine the first target coordinate according to thesensor coordinate of the pixel.

In some embodiments, the locating system may further include acontroller. The locating device may be further configured to transmitthird electronic signals including the locating coordinate to thecontroller. The controller, upon receiving the third electronic signals,may transmit a control signal to at least one of the first image sensoror the second image sensor, causing the at least one of the first imagesensor or the second image sensor to be focused or zoomed in towards thelocating coordinate.

In some embodiments, to generate the marking image according to thedepth image and the plurality of first target coordinates, the markingimage module may be configured to determine disrupting pixels in thedepth image, and determine a second target coordinate for each of thedisrupting pixels. The marking image module may also be configured todetermine an interference range in the target scene according to thesecond target coordinates and a target region in the target scene wherethe target object is predicted to appear, and determine anidentification range in the target scene according to the interferencerange and the target region. The identification range may not overlapwith the interference range. The marking image module may further beconfigured to identify first target pixels having third targetcoordinates within the identification range in the depth image, andgenerate the marking image according to the first target pixels.

In some embodiments, the marking image may include second target pixelscorresponding to the first target pixels. The second target pixels mayhave first gray values, and other pixels in the marking image may havesecond gray values.

In some embodiments, to determine the locating coordinate of the targetobject according to the marking image, the locating coordinatedetermination module may be configured to determine a target connectedcomponent in the marking image, determine a locating point in themarking image according to the connected component, and determine thelocating coordinate according to a second image coordinate of thelocating point.

In some embodiments, to determine the target connected component in themarking image, the locating coordinate determination module may beconfigured to determine at least one connected component in the markingimage, and identify a connected component having a number of pixelsgreater than or equal to a preset threshold from the at least oneconnected component as the target connected component.

According yet to another aspect of the present disclosure, a method forlocating a target object in a target scene may include obtaining, by alocating device, a depth image of the target scene. The depth image mayinclude a plurality of pixels. The method may also include, for each ofthe plurality of pixels of the depth image, determining, by the locatingdevice, a first target coordinate under a target coordinate system. Themethod may further include generating, by the locating device, a markingimage according to the depth image and the first target coordinates ofthe plurality of pixels in the depth image. The marking image mayrepresent potential target objects in the depth image. The method mayalso include determining, by the locating device, a locating coordinateof the target object under the target coordinate system according to themarking image.

According yet to another aspect of the present disclosure, anon-transitory computer readable medium may store instructions. Theinstructions, when executed by a processor, may cause the processor toexecute operations. The operation may include obtaining a depth image ofthe target scene. The depth image may include a plurality of pixels. Theoperation may also include, for each of the plurality of pixels of thedepth image, determining a first target coordinate under a targetcoordinate system. The operation may further include generating amarking image according to the depth image and the first targetcoordinates of the plurality of pixels in the depth image. The markingimage may represent potential target objects in the depth image. Theoperation may also include determining a locating coordinate of thetarget object under the target coordinate system according to themarking image.

Additional features will be set forth in part in the description whichfollows, and in part will become apparent to those skilled in the artupon examination of the following and the accompanying drawings or maybe learned by production or operation of the examples. The features ofthe present disclosure may be realized and attained by practice or useof various aspects of the methodologies, instrumentalities andcombinations set forth in the detailed examples discussed below.

BRIEF DESCRIPTIONS OF THE DRAWINGS

The present disclosure is further described in terms of exemplaryembodiments. These exemplary embodiments are described in detail withreference to the drawings. The drawings are not to scale. Theseembodiments are non-limiting exemplary embodiments, in which likereference numerals represent similar structures throughout the severalviews of the drawings, and wherein:

FIG. 1 is a schematic diagram illustrating an exemplary locating systemaccording to some embodiments of the present disclosure;

FIG. 2 illustrates an exemplary computing device for implementing one ormore components of the locating system;

FIG. 3 is a schematic diagram illustrating an exemplary locating deviceaccording to some embodiments of the present disclosure;

FIG. 4 is a schematic diagram illustrating an exemplary locating processaccording to some embodiments of the present disclosure;

FIG. 5 is a schematic diagram illustrating an exemplary locating processaccording to some embodiments of the present disclosure;

FIG. 6 is a schematic diagram illustrating exemplary relationships amongan image coordinate system, a camera coordinate system, a targetcoordinate system according to some embodiments of the presentdisclosure;

FIG. 7 is a schematic diagram illustrating an exemplary backgroundmarking image according to some embodiments of the present disclosure;

FIG. 8 is a schematic diagram illustrating an exemplary marking imageaccording to some embodiments of the present disclosure; and

FIG. 9 is a schematic diagram illustrating an exemplary marking imageobtained by denoising the marking image illustrated in FIG. 8 accordingto some embodiments of the present disclosure.

DETAILED DESCRIPTION

The present disclosure is directed to a target locating method anddevice for flexible locating a target object with high locatingaccuracy.

In the following detailed description, numerous specific details are setforth by way of examples to provide a thorough understanding of therelevant disclosure. However, it should be apparent to those skilled inthe art that the present disclosure may be practiced without suchdetails. In other instances, well known methods, procedures, systems,components, and/or circuitry have been described at a relativelyhigh-level, without detail, in order to avoid unnecessarily obscuringaspects of the present disclosure. Various modifications to thedisclosed embodiments will be readily apparent to those skilled in theart, and the general principles defined herein may be applied to otherembodiments and applications without departing from the spirit and rangeof the present disclosure. Thus, the present disclosure is not limitedto the embodiments shown, but to be accorded the widest range consistentwith the claims.

The terminology used herein is for the purpose of describing particularexample embodiments only and is not intended to be limiting. As usedherein, the singular forms “a,” “an,” and “the” may be intended toinclude the plural forms as well, unless the context clearly indicatesotherwise. It will be further understood that the terms “comprise,”“comprises,” and/or “comprising,” “include,” “includes,” and/or“including,” when used in this specification, specify the presence ofstated features, integers, steps, operations, elements, and/orcomponents, but do not preclude the presence or addition of one or moreother features, integers, steps, operations, elements, components,and/or groups thereof.

It will be understood that the term “system,” “unit,” “module,” and/or“block” used herein are one method to distinguish different components,elements, parts, section or assembly of different level in ascendingorder. However, the terms may be displaced by another expression if theyachieve the same purpose.

Generally, the word “module,” “sub-module,” “unit,” or “block,” as usedherein, refers to logic embodied in hardware or firmware, or to acollection of software instructions. A module, a unit, or a blockdescribed herein may be implemented as software and/or hardware and maybe stored in any type of non-transitory computer-readable medium oranother storage device. In some embodiments, a softwaremodule/unit/block may be compiled and linked into an executable program.It will be appreciated that software modules can be callable from othermodules/units/blocks or from themselves, and/or may be invoked inresponse to detected events or interrupts.

Software modules/units/blocks configured for execution on computingdevices (e.g., processor 210 as illustrated in FIG. 2 -A) may beprovided on a computer-readable medium, such as a compact disc, adigital video disc, a flash drive, a magnetic disc, or any othertangible medium, or as a digital download (and can be originally storedin a compressed or installable format that needs installation,decompression, or decryption prior to execution). Such software code maybe stored, partially or fully, on a storage device of the executingcomputing device, for execution by the computing device. Softwareinstructions may be embedded in firmware, such as an EPROM. It will befurther appreciated that hardware modules/units/blocks may be includedin connected logic components, such as gates and flip-flops, and/or canbe included of programmable units, such as programmable gate arrays orprocessors. The modules/units/blocks or computing device functionalitydescribed herein may be implemented as software modules/units/blocks,but may be represented in hardware or firmware. In general, themodules/units/blocks described herein refer to logicalmodules/units/blocks that may be combined with othermodules/units/blocks or divided into sub-modules/sub-units/sub-blocksdespite their physical organization or storage. The description may beapplicable to a system, an engine, or a portion thereof.

It will be understood that when a unit, engine, module or block isreferred to as being “on,” “connected to,” or “coupled to,” anotherunit, engine, module, or block, it may be directly on, connected orcoupled to, or communicate with the other unit, engine, module, orblock, or an intervening unit, engine, module, or block may be present,unless the context clearly indicates otherwise. As used herein, the term“and/or” includes any and all combinations of one or more of theassociated listed items.

It may be noted that, the term “image” used in this disclosure generallyrelates to still pictures, motion pictures, videos (offline or livestreaming), frames of a video, or the like, or a combination thereof.The basic unit of an image may also be generally referred to as a pixel.

These and other features, and characteristics of the present disclosure,as well as the methods of operation and functions of the relatedelements of structure and the combination of parts and economies ofmanufacture, may become more apparent upon consideration of thefollowing description with reference to the accompanying drawings, allof which form a part of this disclosure. It is to be expresslyunderstood, however, that the drawings are for the purpose ofillustration and description only and are not intended to limit therange of the present disclosure.

FIG. 1 is a schematic diagram illustrating an exemplary locating systemaccording to some embodiments of the present disclosure. As shown,locating system 100 may include an image capturing mechanism 110, alocating device 120, a controller 130, a storage 140, and a network 150.

The image capturing mechanism 110 may be configured to capture aplurality of images of a target scene 160. The image capturing mechanismmay include a plurality of image sensors for capturing a plurality ofimages (or be referred to as an original image) of the target scene 160simultaneously. The image sensors may be cameras, thermal imagers,and/or any other imaging components capable of sensing the target scene160 and generating images thereof.

In some embodiments, the image sensors may be integrated into a samedevice (as illustrated in FIG. 1 ). For example, the image capturingmechanism 110 may be a binocular camera including a left (with respectto the binocular camera) camera 111 and a right camera 112. In someembodiments, when the two cameras of the binocular camera aresufficiently close to each other, the two original images may besubstantially similar to each other. Accordingly, pixels in the twooriginal images may correspond with respect to each other. For example,when the two cameras simultaneously take images (i.e., a first image anda second image) to a same scene, each pixel in the first image (or atleast a majority part of it) taken by the first camera may one-to-onecorrespond with a pixel in the second image taken by the second camera.

In some embodiments, the image sensors may be included by a plurality ofdevices. For example, the image sensors may each be a standalone cameraand act in cooperation to obtain original images of the target scene.

The image capturing mechanism 110 may also include other functionaldevices or modules for obtaining original images under differentcircumstance. For example, the image capturing mechanism 110 may includeone or more infrared lights and/or flashlights in cooperation with theimage sensors for capturing images under low-light environments.

The original images captured by the image capturing mechanism 110 may betransmitted to the locating device 120 for locating or be transmitted tothe storage 140 for storage.

The locating device 120 may be configured to locating a target object163 in the target scene 160 according to the original images of thetarget scene 160 taken by the image capturing mechanism 110. The targetobject 163 may be an object of interest in the target scene 160. Atleast part of the target object 163 may be predicted to be appear in atarget region 161 in the target scene. The locating device 120 may alsobe capable of distinguish the target object 163 from one or moreinterferents 162 presented in the target region. The locating device 120may be implemented by a computing device 200 as illustrated in FIG. 2 orone or more logic circuits.

In some embodiment, the target object 163 may be determined according tothe target region 161. For example, the target region 161 may bepredetermined, and an object may be identified as a target object for areason that at least part of it appears in the target region 161. Insome embodiments, the property of the target object 163 and the targetregion 161 may be both predetermined, and only an object with thepredetermined property entering into the target region 161 may beidentified as a target object.

In some embodiments, the target region 161 may be determined accordingto the target object 163. For example, the target object 163 may bepredetermined, and a region in the target scene may be set as a targetregion for a reason that at least part of the target object 163 has ahigh possibility to appear in that region.

The target scene 160, the target region 161, and the target object 163may be set according to an application field of the locating system 100.Three exemplary application field of the locating system 100 aredescribed below, which are only for demonstration purposes and notintended to be limiting.

In a first exemplary application field, the target object 163 may be astand-up person, the target scene 160 may be a conference room. Thetarget region 161 may be set according to the height distribution of thestand-up person so that at least a part of the stand-up person may beincluded in the target region 161. A sit-down person may not be includedin the target region 161 or be treated like an interferent.

In a second exemplary application field, the target scene 160 may be aregion under surveillance and the target region 161 may be a restrictedarea or a key area (e.g., entrance, exit, corridor) within the targetscene 160. The target object 163 may be a potential intruder presentedin the target region 161.

In a third exemplary application field, the image capturing mechanism110 may be installed on a vehicle, and the target scene 160 may be aroad view. The target region 161 may be a region adjacent to the vehicleand possibly be a blind zone of a driver (human or electronic) of thevehicle. The target object 163 may be an obstacle (e.g., pedestrian,vehicle, building) presented in the target region 161.

The locating device 120 may obtain a depth image according to theoriginal obtain images from the image capturing mechanism 110 or thestorage 140 and generate a depth image (may also be referred to as arange image) therefrom. The depth image may represent distances topoints in the target scene 160 corresponding to pixels of the depthimage from a reference point associated with the image capturingmechanism 110 (e.g., an optical center of one of the cameras included inthe image capturing mechanism 110). The locating device 120 maydetermine a coordinate for each of a first plurality of pixels of thedepth image under a target coordinate system (i.e., a world coordinatesystem) and generate a marking image according to the depth image andthe determined coordinates. The marking image may represent objects inthe depth image that may potentially be the target object 163 (or bereferred to as potential target objects). Then the locating device 120may determine the target object 163 in the marking image and obtain atarget coordinate (or be referred to as a locating coordinate) of thetarget object 163 under a target coordinate system. Here, a coordinatesystem may mean a measurement of a scene, such as a perspective ofobservation of the scene. For example, for a particular scene inside abuilding, if the camera that takes an image of the scene is mounted on aceiling of the building, the image may be treated as a measurement ofthe scene from the camera coordinate, i.e., a coordinate using thecenter (e.g., optic center) of the image sensor (e.g., CCD or CMOS) ofthe camera as origin. The target coordinate system may be a coordinatesystem to measure the objects in the scene from a reference point fromthe reference point's perspective. For example, the reference point maybe a predetermined point in the space, such as a point on the floor ofthe building.

More description of the locating device 120 and related locating processare provided elsewhere in the present disclosure (e.g., in connectionwith FIGS. 3, 4, 5 ).

In some embodiments, the locating device 120 may determine a pluralityof target objects 163 in the target scene 161 and obtain a plurality ofcorresponding locating coordinates.

The locating coordinate(s) obtained by the locating device 120 may betransmitted to the controller 130 for performing one or more follow-upoperations or be transmitted to the storage 140 for storage.

The controller 130 may obtain the locating coordinate(s) from thelocating device 120 or the storage 140 and perform one or more follow-upoperations according to the target coordinate(s). Exemplary follow-upoperations may include but not limited to: tracking the target object163, zooming in and/or focusing the image capturing mechanism 110towards the target object 163 (e.g., to give the target object 163 aclose-up shooting to obtain a featured image 170 of the target object163), recording the target object 163 (e.g., a stand-up person),changing an image capturing mode of the image capturing mechanism 110(e.g., to enhance an image quality of one or more obtained images),identifying the target object 163, transmitting an image of the targetobject 163 to a station (e.g., a police station, a surveillance center)or to a terminal (e.g., a mobile phone, a desktop, a laptop) through thenetwork 150, alarming, controlling a vehicle including the imagecapturing mechanism 110 so as to avoid the target object 163, or thelike, or a combination thereof.

The storage 140 may store data, instructions, and/or any otherinformation. In some embodiments, the storage 140 may store dataobtained from the image capturing mechanism 110, the locating device120, the controller 130, and any other device included in the locatingsystem 100 not shown in FIG. 1 . For example, the storage 140 may storedata and/or instructions that the locating device 120 may execute or useto perform exemplary methods described in the present disclosure. Thestorage 140 may include a mass storage device, a removable storagedevice, a volatile read-and-write memory, a read-only memory (ROM), orthe like, or any combination thereof. In some embodiments, the storage140 may be implemented on a cloud platform.

The image capturing mechanism 110, the locating device 120, thecontroller 130, and the storage 140 may communicate data and/orinformation via one or more cables and/or the network 150. The network150 may include any suitable network that can facilitate the exchange ofinformation and/or data for the locating system 100. The network 150 maybe and/or include a public network (e.g., the Internet), a privatenetwork (e.g., a local area network (LAN), a wide area network (WAN)), awired network (e.g., an Ethernet network), a wireless network (e.g., an802.11 network, a Wi-Fi network), a cellular network (e.g., a Long TermEvolution (LTE) network), a frame relay network, a virtual privatenetwork (“VPN”), a satellite network, a telephone network, routers,hubs, switches, server computers, and/or any combination thereof. Merelyby way of example, the network 150 may include a cable network, awireline network, a fiber-optic network, a telecommunications network,an intranet, a wireless local area network (WLAN), a metropolitan areanetwork (MAN), a public telephone switched network (PSTN), a Bluetooth™network, a ZigBee™ network, a near field communication (NFC) network, orthe like, or any combination thereof. In some embodiments, the network150 may include one or more network access points. For example, thenetwork 150 may include wired and/or wireless network access points suchas base stations and/or internet exchange points through which one ormore components of the locating system 100 may be connected to thenetwork 150 to exchange data and/or information.

In some embodiments, images obtained by the image capturing mechanism110 may also be used to generate a stereo image. For example, thelocating system 100 may further include an image processing deviceconfigured to generate a stereo image according to the images obtainedby the image capturing mechanism 100. For example, after the locatingdevice 120 obtain a locating coordinate of the target object 163, thecontroller 130 may cause the image capturing mechanism 110 to shoot thetarget object 163 in close-up for obtaining a plurality of featuredimages 170. The image processing device may process the plurality offeatured images 170 and generate a stereo image therefrom.

In some embodiments, the locating system 100 may include a camera (notshown in FIG. 1 ) configured to obtain a depth image of the target scenedirectly. The locating device 120 may analyze the depth image obtainedby the range camera to determine the locating coordinate of the targetobject 163 under the target coordinate system. Other image sensor(s) maybe optional for the locating of the target object 163. In someembodiments, the image capturing mechanism 110 may only include a rangecamera. Alternatively, the image capturing mechanism 110 may include arange camera and one or more generally purposed cameras. The rangecamera is known in the art and descriptions of which are not repeatedhere.

It should be noted that the above description about the locating system100 is only for illustration purposes, and is not intended to limit thepresent disclosure. It is understandable that, after learning the majorconcept and the mechanism of the present disclosure, a person ofordinary skill in the art may alter the locating system 100 in anuncreative manner. The alteration may include combining and/or splittingmodules or sub-modules, adding or removing optional modules orsub-modules, etc. For example, the locating device 120, the controller130, and/or the storage 140 may be integrated into the image capturingmechanism 100 (e.g., a binocular camera). As another example, thelocating device 120 and the controller 130 may also be implemented usinga same computing device (e.g., computing device 200 illustrated in FIG.2 ). All such modifications are within the protection range of thepresent disclosure.

FIG. 2 illustrates an exemplary computing device for implementing one ormore components of the locating system (e.g., locating device 120,controller 130). For example, the computing device 200 may be configuredto perform one or more operations disclosed in the present disclosure.The computing device 200 may include a bus 270, a processor 210, a readonly memory (ROM) 230, a random-access memory (RAM) 240, a storage 220(e.g., massive storage device such as a hard disk, an optical disk, asolid-state disk, a memory card, etc.), an input/output (I/O) port 250,and a communication interface 260. It may be noted that, thearchitecture of the computing device 200 illustrated in FIG. 2 is onlyfor demonstration purposes, and not intended to be limiting.

In some embodiments, the computing device 200 may be a single device.Alternatively, the computing device 200 may include a plurality ofcomputing devices having a same or similar architecture as illustratedin FIG. 2 , and one or more components of computing device 200 may beimplemented by one or more of the plurality of computing devices.

The bus 270 may couple various components of computing device 200 andfacilitate transferring of data and/or information between them. The bus270 may have any bus structure in the art. For example, the bus 270 maybe or may include a memory bus and/or a peripheral bus.

The I/O port 250 may allow a transferring of data and/or informationbetween the bus 270 and a peripheral device (e.g., components of thelocating system 100 such as the image capturing mechanism 110). The I/Oport 250 may include a USB port, a COM port, a PS/2 port, an HDMI port,a VGA port, a video cable socket such as an RCA sockets and a Mini-DINsocket, or the like, or a combination thereof.

The communication interface 260 may allow a transferring of data and/orinformation between the network 150 and the bus 270. For example, thecommunication interface 260 may be or may include a network interfacecard (NIC), a Bluetooth™ module, an NFC module, etc.

The ROM 230, the RAM 240, and/or the storage 220 may be configured tostore computer readable instructions that can be executed by theprocessor 210. The RAM 240, and/or the storage 220 may store date and/orinformation obtained from a peripheral device (e.g., the image capturingmechanism 100) and/or the network 150. The RAM 240, and/or the storage220 may also store date and/or information generated by the processor210 during the execution of the instruction. In some embodiments, theROM 230, the RAM 240, and/or the storage 220 may be or may include thestorage 130 illustrated in FIG. 1 .

The processor 210 may be or include any processor in the art configuredto execute computer readable instructions (e.g., stored in the ROM 230,the RAM 240, and/or the storage 220), so as to perform one or moreoperations disclosed in the present disclosure. For example, theprocessor 210 may perform locating of a target object (e.g., the targetobject 163) in a process illustrated in FIG. 4 or FIG. 5 .

FIG. 3 is a schematic diagram illustrating an exemplary locating deviceaccording to some embodiments of the present disclosure. Locating device300 may be an exemplary embodiment of the locating device 120 and may beconfigured perform locating of a target object (e.g., the target object163 in FIG. 1 ) present in a target region (e.g., the target region 161in FIG. 1 ) of a target scene (e.g., the target scene 160 in FIG. 1 ).The locating device 300 may be configured to perform the processillustrated in FIG. 4 and/or FIG. 5 .

The locating device 300 may include an acquisition module 310 and aprocessing module 320. The processing module 320 may include a depthimage unit 321, a coordinate determination unit 322, a marking imageunit 323, and a locating coordinate determination unit 324. Additionalmodules and or units may also be included in the locating device 300 forfacilitating the locating of the target object. The acquisition module310, the processing module 320 and the units thereof may be implementedby the processor 210 illustrated in FIG. 2 .

The acquisition module 310 may be configured to obtain a first originalimage and a second original image of the target scene. The first imageand the second image may be taken by a first image sensor and a secondimage sensor of the image capturing mechanism 110 simultaneously. Theacquisition unit 501 may obtain the first original image and the secondoriginal image from the first image sensor and the second image sensor.Alternatively or additionally, the first original image and the secondoriginal image may be temporary stored in a storage device (e.g., thestorage 140, the storage 220, the RAM 240) and the acquisition unit 501may obtain the first original image and the second original image fromthe storage device.

The acquisition unit 501 may obtain the first original image and thesecond original image via a communication module (e.g., the bus 270, theI/O port 250, and/or the communication interface 260) of the locatingdevice 300. For example, the acquisition unit 501 may receive firstelectronic signals including the first image and second electronicsignals including the second image via the communication module.

In some embodiments, the acquisition module 310 may be configured toacquire two original images of the target scene respectively taken by aleft camera and a right camera of a binocular camera (the imagecapturing mechanism 110).

In some embodiments, the acquisition unit 310 may directly obtain adepth image taken by a range camera.

The processing module 320 may be configured to perform operationsdescribed as following.

The processing module 320, or the depth image unit 321 may obtain adepth image of the target scene. The processing module 320, or the depthimage unit 321, may generate a depth image of the target scene accordingto the original images obtained by the acquisition unit 310.Alternatively, the processing module 320, or the depth image unit 321,may directly obtain a depth image taken by a range camera from theacquisition unit 310. Gray values of pixels of the depth image mayrepresent a distance to points in the target scene 160 corresponding tothe pixels of the depth image from a point associated with the imagecapturing mechanism 110.

In some embodiments, the processing module 320, or the depth image unit321, may determine a depth image according to two original imagesobtained by a binocular camera. A gray value of any pixel in the depthimage may be a value of a horizontal parallax (e.g., the parallax in adirection of the XI axis illustrated in FIG. 6 ) between pixelscorresponding to a target actual position in the two original images.The target actual position may be an actual position corresponding tothe pixels of the depth image in the target scene.

The processing module 320, or the coordinate determination unit 322, maydetermine a coordinate (or be referred to as a first target coordinate)of an actual position corresponding to each of a plurality of pixels ofthe depth image under a target coordinate system. The target coordinatesystem may be a three-dimensional coordinate system describing actualpositions of objects showed by the depth image and/or the originalimages in the target scene. The plurality of pixels may be all thepixels of the depth image, pixels corresponding to the target region, orpixels determined by performing a sampling technique upon the depthimage.

In some embodiments, the processing module 320, or the coordinatedetermination unit 322, may determine a three-dimensional coordinate ofan actual position corresponding to each pixel of the depth image underthe target coordinate system;

The processing module 320, or the marking image unit 323, may generate amarking image (or mask) according to the depth image. The marking imagemay represent potential target objects in the depth image. Theprocessing module 320, or the marking image unit 323 may determine anidentification range (e.g., preset range for identification) in thedepth image and generate the marking image according to a position (orimage coordinate) distribution of the pixels within the identificationrange (preset range for identification). The identification range maycorrespond to the whole target region or a part of the target regionwithout an interferent (or at least a majority of it). In someembodiments, the processing module 320 may determine an interferencerange represents a region of the target scene including one or moreinterferents. The processing module 320 may determine the identificationrange according to the interference range and the target region, and theidentification range may not overlap with the interference range.

In some embodiments, the processing module 320, or the marking imageunit 323, may sift out (e.g., select and/or identify) and/or selectfirst target pixels from the depth image and generate a marking imageaccording to position (or image coordinate) distribution of the firsttarget pixels in the depth image. The three-dimensional coordinates ofactual positions corresponding to the first target pixels under thetarget coordinate system may be within the preset range (e.g., anidentification range/range). The marking image may include a pluralityof second target pixels corresponding to the first target pixels. Grayvalues of the second target pixels in the marking image may be firstgray values, gray values of other pixels in the marking image may besecond gray values. The second target pixels, of which the position (orimage coordinate) in the marking image may be the same as the position(or image coordinate) of the first target pixels in the depth image, mayhave a gray value as the first gray value.

The processing module 320, or the locating coordinate determination unit324, may determine at least one connected component (or be referred toas connected region or connected domain) in the marking image. Any pixelin a connected component may be adjacent to at least one other pixel inthe same connected component. A pixel in the connected component andwhich is adjacent to any one of the pixels in the connected componentmay have a gray value within a preset gray value range. The preset grayvalue range may include the first gray value(s) but not the second grayvalue(s). To put it in other words, the connected component may have aplurality of pixels adjacent with each other. The gray values of all thepixels in the connected component may be within the preset gray valuerange. The preset gray value range includes the first gray value(s) butexcludes the second gray value(s).

The processing module 320, or the locating coordinate determination unit324, may identify those connected components that are large enough, andthen identify the center points of these identified connectedcomponents, and then treat the 3D target coordinates of the centerpoints as the coordinates of the target objects in the target scene.

For example, the processing module 320, or the locating coordinatedetermination unit 324, may sift out (e.g., select and/or identify) atarget connected component with a number of pixels greater than or equalto a preset threshold from the at least one connected component,determine a locating point in the marking image according to the targetconnected component; and determine the locating coordinate according toan image coordinate of the locating point (second image coordinate).

In some embodiments, the locating point may be a center of the targetconnected component. The processing module 320, or the locatingcoordinate determination unit 324, may designate a three-dimensionalcoordinate (or be referred to as a fourth target coordinate) of anactual position corresponding to a center of the target connectedcomponent under the target coordinate system as the three-dimensionalcoordinate (locating coordinate) of the target object in the targetscene.

In some embodiments, to generate the depth image according to the firstimage and the second image, the processing module 320, or the depthimage unit 321 may be configured to perform a process described asfollowing.

For each pixel in the first original image (i.e., any one of the twooriginal images), the processing module 320, or the depth image unit321, may determine a horizontal parallax between the pixel of the firstoriginal image and a corresponding pixel of the second original image.

Next, for each pixel in the first original image, the processing module320, or the depth image unit 321, may assign the correspondinghorizontal parallax value to the pixel as its gray scale value (grayvalue), and thereby generating the depth image. In other words, theprocessing module 320, or the depth image unit 321, may perform thefollowing operation with respect to the horizontal parallax determinedfor each pixel in the first original image: taking the horizontalparallax determined for the pixel as a gray value of a pixel having asame position in the depth image as the position of the pixel in firstoriginal image, and then generate the depth image according to the grayvalue of each pixel in the depth image.

In some embodiments, to determining a three-dimensional coordinate(first target coordinate) of the actual position corresponding to eachof the plurality of pixels in the depth image under the targetcoordinate system, the processing module 320, or the coordinatedetermination unit 322, may be configured to perform a process describedas following.

The processing module 320, or the coordinate determination unit 322, maydetermine a three-dimensional coordinate (sensor or camera coordinate)for each of the plurality of pixels under a sensor coordinate systemwith respect to the first image sensor according to an image coordinateand a gray value of each of the plurality of pixels. In someembodiments, the first image sensor may belong to a binocular camera,the first image sensor may be a left camera or a right camera of thebinocular camera, correspondingly, the camera and/or sensor coordinatesystem may be a camera coordinate system of the left camera or the rightcamera.

The processing module 320, or the coordinate determination unit 322, mayalso determine a three-dimensional coordinate (the first targetcoordinate) of the actual position corresponding to each of theplurality of pixels under the target coordinate system according to thethree-dimensional coordinate (sensor and/or coordinate) of each of theplurality of pixels under the sensor coordinate system.

In some embodiments, the identification range (preset range foridentification) may be a three-dimensional coordinate range within whicha target object in the target scene may actually be (or be predicted tobe) under the target coordinate system.

In some embodiments, to generate the marking image, the processingmodule 320, or the marking image unit 323, may be configured to performa process described as following.

The processing module 320, or the marking image unit 323, may determineat least one interferent (object that disrupts, or causes interferenceto the detection of the target object) in the target scene (ordisrupting pixels in the depth image) and determine a three-dimensionalcoordinate (or be referred to as a second target coordinate) of the atleast one interferent (or each of the disrupting pixels) under thetarget coordinate system;

The processing module 320, or the marking image unit 323, may alsodetermine an interference range in the target scene according to thethree-dimensional coordinate(s) (second target coordinates) of the atleast one interferent (or disrupting pixels) under the target coordinatesystem;

The processing module 320, or the marking image unit 323, may furtherdetermine an identification range (preset range) in the target sceneaccording to the interference range (disrupt range) and the targetregion, wherein the identification range does not overlap with theinterference range.

The processing module 320, or the marking image unit 323, may also siftout (e.g., select and/or identify) pixels of which the correspondingactual positions have three-dimensional coordinates under the targetcoordinate system (or be referred to as third target coordinates) in theidentification range in the depth image. The pixels sifted out may bedesignated as the first target pixels.

In some embodiments, the processing module 320, or the marking imageunit 323, may generate the marking image from the depth image.Specifically, the processing module 320 may do so by assigning and/ordesignating the first target pixels with the first gray values, therebymaking these pixels the second target pixels. For the rest of otherpixels, the processing module 320, or the marking image unit 323 mayfurther designate and/or assign second gray values.

In some embodiments, to determine the target coordinate of the targetobject according to the marking image, the processing module 320, or thelocating coordinate determination unit 324, may determine a targetconnected component in the marking image. The processing module 320, orthe locating coordinate determination unit 324, may also determine alocating point in the marking image according to the target connectedcomponent, and determine the locating coordinate according to a secondimage coordinate of the locating point.

In some embodiments, to determine the target connected component in themarking image, the processing module 320, or the locating coordinatedetermination unit 324, may determine at least one connected componentin the marking image, and sift out (e.g., select and/or identify) aconnected component having a number of pixels greater than or equal to apreset threshold from the at least one connected component as the targetconnected component.

It may be noted that, the above descriptions about the locating device300 are only for illustration purposes, and are not intended to limitthe present disclosure. It is to be understood that, after learning themajor concept and the mechanism of the present disclosure, a person ofordinary skill in the art may alter the locating device 300 in anuncreative manner. The alteration may include combining and/or splittingmodules or units, adding or removing optional modules or units, etc. Allsuch modifications are within the protection range of the presentdisclosure.

FIG. 4 is a schematic diagram illustrating an exemplary locating processaccording to some embodiments of the present disclosure. Process 400 maybe performed by the locating module 300 for locating a target object(e.g., the target object 163) appeared in a target region (e.g., targetregion 161) of a target scene (e.g., the target scene 160). In someembodiments, one or more operations of process 400 illustrated in FIG. 4may be implemented in the locating system 100 illustrated in FIG. 1 .For example, the process 400 illustrated in FIG. 4 may be stored in thestorage 130 in the form of instructions, and invoked and/or executed bythe locating device 140 or the locating module 141. One or moreoperations of the process 400 may be performed by the processor 210 ofthe computing device 200 as illustrated in FIG. 2 which implements thelocating device 140 or the locating module 141.

In step 410, the processor 210, or the depth image unit 321, may obtaina depth image of the target scene. The depth image may include aplurality of pixels. The depth image may represent distances to pointsin the target scene corresponding to the pixels of the depth image froma reference point associated with an image capturing mechanism (e.g.,the image capturing mechanism 110) contribute to the generating of thedepth image. For example, when the image capturing mechanism includes aplurality of cameras, the reference point may be an optical point of oneof the plurality of cameras or be determined according to optical pointsof all the plurality of cameras. As another example, when the imagecapturing mechanism is a range camera, the reference point may be anoptical point or a base point of the range camera.

In some embodiments, the image capturing mechanism may include aplurality of image sensors (e.g., cameras), each of which may obtain anoriginal image of the target scene. The processor 210, or the depthimage unit 321, may generate the depth image according to the obtainedoriginal images of the target scene. For example, the image capturingmechanism may include a first image sensor and a second image sensorconfigured to obtain a first image and a second image of the targetscene simultaneously. The processor 210, or the depth image unit 321,may receive first electronic signals including the first image andsecond electronic signals including the second image through theacquisition module 310 and generate the depth image according to thefirst image and the second image.

In some embodiments, the processor 210, or the depth image unit 321, maydetermine, for each pixel of the first image, a horizontal parallaxbetween each pixel of the first image and a corresponding pixel of thesecond image. The processor 210, or the depth image unit 321, may thendetermine a gray value for each pixel of the depth image according tothe horizontal parallax determined for a corresponding pixel of thefirst image.

In some embodiments, the image capturing mechanism may include a rangecamera configured to obtain a depth image directly. The image capturingmechanism may optionally include additional image sensors which may beinvolved in follow-up operations after the locating coordinate of thetarget object is obtained. The processor 210, or the depth image unit321, may receive electronic signals including the directly obtaineddepth image. The directly obtained depth image may be subject to thenext step of the process 400. Optionally, the depth image unit 321 maypreprocess (e.g., denoise, crop) the depth image.

In step 420, for each of the plurality of pixels of the depth image, theprocessor 120, or the coordinate determination unit 322, may determine afirst target coordinate under a target coordinate system. The pluralityof pixels may be all the pixels of the depth image, pixels correspondingto the target region, or pixels determined by performing a samplingtechnique upon the depth image.

A target coordinate system may be a coordinate system describing actualpositions (or points) corresponding to pixels of an image (e.g., thedepth image and/or the original images) with respect to a scene showedby the image (e.g., the target scene). The first target coordinate maybe a three-dimensional coordinate of an actual position corresponding toeach of the plurality of pixels of the depth image under the targetcoordinate system. For demonstration purposes, exemplary relationshipsamong an image coordinate system (a coordinate system describing aposition of a pixel in an image), a sensor coordinate system (acoordinate system describing actual positions (or points) correspondingto pixels of an image with respect to an image sensor taking the image),and a target coordinate system are illustrated in FIG. 6 . When theimage sensor for taking the image is a camera (e.g., a left camera or aright camera of a binocular camera), the sensor coordinate system mayalso be referred to as a camera coordinate system.

The processor 120, or the coordinate determination unit 322, may obtainthe plurality of first target coordinates according to the relationshipsamong the three coordinate systems. In some embodiments, the depth imageobtained in step 410 may be generate according to a first image taken bya first image sensor and a second image taken by a second image sensor.The processor 120, or the coordinate determination unit 322, maydetermine a sensor coordinate for each of the plurality of pixels undera sensor coordinate system with respect to, for example, the first imagesensor, according to a first image coordinate and a gray value of eachof the plurality of pixels. A first image coordinate may be an imagecoordinate of a pixel in the depth image under an image coordinatesystem X_(I)-Y_(I) as illustrated in FIG. 6 . The processor 120, or thecoordinate determination unit 322, may then determine the first targetcoordinate according to the sensor coordinate of each of the pluralityof pixels.

In some embodiments, the depth image obtained in step 410 may be takenby a range camera. The sensor coordinate system may be with respect toan optical center, or a base point, of the range camera.

An exemplary process for determining the first target coordinate aredescribed elsewhere in the present′ disclosure (e.g., the operations(b1) and (b2) in step 520 of the process 500 illustrated in FIG. 5 ),which is only for demonstration purposes and not intended to belimiting.

In step 430, the processor 120, or the marking image unit 323, maygenerate a marking image according to the depth image and the firsttarget coordinates of the plurality of pixels in the depth image. Themarking image may represent potential target objects in the depth image.For example, the pixels having first gray values in the marking imagemay represent the potential target objects in the target scene, and thepixels having second gray values in the marking image may represent abackground (e.g., objects of no interest) of the target scene.

The first gray values or the second gray values may be equal to acertain value or include a value range. For example, the first grayvalues may all be 200 (or any other proper value) and the second valuesmay all be 0 (or any other proper value not covered by the first grayvalues). As another example, the first gray values may cover a valuerange between 200 and 255. In some embodiments, the first gray valuesmay be determined further on the gray values of the depth image.

In some embodiments, to generate the marking image, the processor 120,or the marking image unit 323, may determine one or more interferents(e.g., in the form of a collection of pixels which may be referred to asdisrupting pixels) in the target region. The processor 120, or themarking image unit 323, may determine a second target coordinate foreach of the disrupting pixels to obtain a plurality of second targetcoordinates. The second target coordinates may be three-dimensionalcoordinates of actual position in the target scene corresponding to thedisrupting pixels under the target coordinate system. The processor 120,or the marking image unit 323, may determine an interference range inthe target scene according to the second target coordinates and thetarget region, and then determine an identification range (preset rangefor identification) in the target scene according to the interferencerange and the target region. The identification range may not overlapwith the interference range. The processor 120, or the marking imageunit 323, may sift out (e.g., select and/or identify) first targetpixels having third target coordinates within the identification rangein the depth image and generate the marking image according to the firsttarget pixels. The marking image may include second target pixelscorresponding to the first target pixels. The second target pixels mayhave first gray values, and other pixels in the marking image havesecond gray values. One of the first target pixels in the depth imageand one of the second target pixels in the marking image may have a sameposition (or image coordinate).

In some embodiments, the plurality of the pixels for determining thefirst target coordinates may correspond to the target region. Theidentification range (preset range for identification) may be determinedby excluding disrupting pixels from the plurality of the pixels. In someembodiments, the plurality of the pixels for determining the firsttarget coordinates may be all the pixels of the depth image, theidentification range may be determined by first determining pixelscorresponding to the target region, then exclude the disrupting pixelsform the determined pixels. In some embodiments, the processor 120, orthe marking image unit 323, the marking image may be generated accordingto all pixels corresponding to the target region in the depth imagewithout excluding disrupting pixels.

In step 440, the processor 210, or the locating coordinate determinationunit 324, may determine a locating coordinate of the target object underthe target coordinate system according to the marking image. Forexample, the processor 210, or the locating coordinate determinationunit 324, may determine a target connected component representing thetarget object in the marking image, and determine a locating point inthe marking image according to the target connected component. Theprocessor 210, or the locating coordinate determination unit 324, maythen determine the locating coordinate according to a second imagecoordinate of the locating point. The processor 210, or the locatingcoordinate determination unit 324, may first determine at least oneconnected component in the marking image, and then sift out (e.g.,select and/or identify) the target connected component from the at leastone connected component.

In some embodiments, to determine the target connected component, theprocessor 210, or the locating coordinate determination unit 324, mayfirst determine at least one connected component in the marking image,and sift out (e.g., select and/or identify) a connected component havinga number of pixels greater than or equal to a preset threshold from theat least one connected component as the target connected component. Thepreset threshold may be set according to a possible size of the targetobject.

In some embodiments, the type of the target object may be predetermined.To determine the target connected component, the processor 210, or thelocating coordinate determination unit 324, may perform an imagerecognition upon the marking image, the depth image, and/or the originalimages for generating the depth image, for recognizing an objectcorresponding to the at least one connected component. The targetconnected region may be determined according to the recognition result.For example, the image recognition may be according to the shape and/orgray values of pixels of the at least one connected component.

In some embodiments, the processor 210, or the locating coordinatedetermination unit 324, may denoise the marking image before determiningthe target connected component. The image denoising may be performed inany process in the art. An exemplary process is provided elsewhere inthe present disclosure (e.g., operations (d1) to (d4) in the step 540 ofprocess 500 illustrated in FIG. 5 ).

The locating point may be a point indicating a position of the targetobject in the marking image, the depth image, or the first originalimage. In some embodiments, the locating point may be a central pixel ofthe target connected component. In some embodiments, the locating pointmay be determined according to the shape and/or the recognition resultof the target connected component. For example, the locating point maybe determined so that it may be a center of head or face of a stand-upperson.

In some embodiments, after the target connected component is determined,the processor 210, or the locating coordinate determination unit 324 maysegment the depth image and/or the original images according to thetarget connected component. For example, the target connected componentmay be used to determine seed points and/or thresholds for the imagesegmentation. The locating point may be determined according to theimage segmentation result.

The locating coordinate under the target coordinate system may bedetermined according to an image coordinate of the locating point.

In some embodiments, after the locating coordinate is determined, thelocating device 300 may transmit the locating coordinate to a controller(e.g., the controller 130) to perform one or more follow-up operations.For example, the locating device 300 may transmit third electronicsignals including the locating coordinate to the controller. Thecontroller, upon receiving the third electronic signals, may transmit acontrol signal to the image capturing mechanism (e.g., the imagecapturing mechanism 110) for generating the original images or the depthimage, causing the image capturing mechanism perform a correspondingoperation. For example, the image capturing mechanism (e.g., a binocularcamera) may include a first image sensor and a second image sensor. Thecontrol signal may cause at least one the first image sensor and thesecond image sensor to be focused or zoomed in towards the locatingtarget coordinate.

It may be noted that the above descriptions of locating of the targetobject are only for demonstration purposes and not intended to belimiting. It is to be understood that, after learning the major conceptand the mechanism of the present disclosure, a person of ordinary skillin the art may alter process 400 in an uncreative manner. For example,the operations above may be implemented in an order different from thatillustrated in FIG. 4 . One or more optional operations may be added toprocess 400. One or more operations may be divided or be combined. Allsuch modifications are within the protection range of the presentdisclosure.

FIG. 5 is a schematic diagram illustrating an exemplary locating processaccording to some embodiments of the present disclosure. Process 500 maybe performed by the locating module 300 to achieve the process 400illustrated in FIG. 4 . In some embodiments, one or more operations ofprocess 500 illustrated in FIG. 5 may be implemented in the locatingsystem 100 illustrated in FIG. 1 . For example, the process 500illustrated in FIG. 5 may be stored in the storage 130 in the form ofinstructions, and invoked and/or executed by the locating device 140 orthe locating module 141. One or more operations of the process 500 maybe performed by the processor 210 of the computing device 200 asillustrated in FIG. 2 which implements the locating device 140 or thelocating module 141. The process 500 may include:

Step 510: the processor 210, or the depth image unit 321, may obtain twooriginal images of a target scene respectively taken by a left camera(e.g., left camera 610 illustrated in FIG. 6 ) and a right camera (e.g.,left camera 620 illustrated in FIG. 6 ) of a binocular camera, anddetermine a depth image according to the two original images. Step 510may be performed to achieve step 410 of process 400 illustrated in FIG.4 .

The depth image may be a gray scale image with a plurality of pixels.Each pixel in the depth image corresponds to a pixel in one of theoriginal images (either the left image or the right image). Further, thevalue (gray value or gray scale value) of each pixel in the depth imagemay be determined according to a horizontal parallax (e.g., the parallaxalong the direction of the XI axis as illustrated in FIG. 6 ) betweenpixels corresponding to a target actual position in the two originalimages. For example, a value of the horizontal parallax (e.g., measuredin pixels, distance, degrees, or radians) may be set as a gray value ofa corresponding pixel in the depth image. The target actual position maybe an actual position corresponding to the pixel of the depth image inthe target scene. Accordingly because each the pixels in the originalimage is kept in the same position in the depth image, the depth imagemaintains the position information of every object in the originalimage. Further, because the gray value of each pixel represents adistance of a corresponding points on the objects from the camera, thedepth image includes position information of the objects in a 3-D space.

In some embodiments, before shooting the target scene using thebinocular camera, a user may install the binocular camera at a place ashigh as possible (but reasonably), so that a field of view (FOV) of thebinocular camera may cover the location of the target scene. A baseline(e.g., as illustrated in FIG. 6 ) of the binocular camera may be made tobe parallel with the ground (e.g., along the direction of the Xc axis asillustrated in FIG. 6 ), wherein the baseline of the binocular camera isa linear segment between lenses (optical centers of the lenses) of theleft camera and the right camera of the binocular camera. Afterinstallation, the left camera and the right camera of the binocularcamera may shoot the target scene respectively, and two original imagesmay be generated. The two original images may include a first originalimage and a second original image. The first original image may be takenby the left camera and the second original image may be taken by theright camera, or vice versa.

In some embodiments, after the processor 210, or the depth image unit321, obtains the two original images of the target scene respectivelycaptured by the left camera and the right camera of the binocularcamera, the processor 210 (or the depth image unit 321) may determinethe depth image according to the two original images. In some detailedembodiments, the determination may include a three-step processdescribed as following:

(a1) The processor 210, or the depth image unit 321, may determine, foreach pixel of the first original image, a horizontal parallax betweencorresponding pixels in the two original images. The correspondingpixels may correspond to an actual position corresponding to each pixel.The pixels in the two original images may correspond to a target actualposition where each pixel corresponds to. The first original image maybe any one of the two original images.

(a2) For the horizontal parallax determined for each pixel of the firstoriginal image, the processor 210, or the depth image unit 321, may takethe value of the horizontal parallax (or a parameter generatedtherefrom) determined for each pixel in (a1) as a gray value of acorresponding pixel for the depth image. The pixel for the depth imagemay be set as having a same position (or image coordinate) as each pixelin the first original image; and

(a3) The processor 210, or the depth image unit 321, may generate thedepth image according to the gray value of each pixel for the depthimage.

In some embodiments, in aforementioned step (a1), the horizontalparallax may also be referred to as depth. For determining thehorizontal parallax between pixels in the two original imagescorresponding to each pixel in the first original image, the processor210 may adopt an algorithm including but not limited to a Boyer-Moore(BM) algorithm, a Semi-Global Block Matching (SGBM) algorithm, or anyalgorithm for obtaining the depth in the art, or a combination thereof.

In some embodiments, after the depth image is generated according to theaforementioned step, a position (or image coordinate) of a pixel in thedepth image may correspond to a position (or image coordinate) of apixel in the first original image.

Step 520: from the above description, the target scene may include oneor more objects. Each pixel in the original image may correspond to apoint on the surface of the one or more objects. The pixels in theoriginal image may one-to-one correspond to the pixels in the depthimage. In this step, for each pixel in the depth image, the processor210 and/or the coordinate determination unit 322 may further determinethe actual position of the point corresponding to the pixel under atarget coordinate system. In other words, the processor 210, and/or thecoordinate determination unit 322, may further determine athree-dimensional coordinate (first target coordinate) of the actualposition corresponding to each pixel of the depth image under a targetcoordinate system (e.g., as illustrated in FIG. 6 ). Step 520 may beperformed to achieve step 420 of process 400.

In some embodiments, the processor 210, and/or the coordinatedetermination unit 322, may determine the above three-dimensionalcoordinate in a two-step process described as following:

(b1) The processor 210, or the coordinate determination unit 322, maydetermine a three-dimensional coordinate (camera coordinate) for eachpixel of the depth image under a camera coordinate system (thecoordinate set on the camera of the original image) according to acoordinate (image coordinate, the coordinate of the pixel in the depthimage) of each pixel of the depth image under an image coordinate systemand the gray value of each pixel. The camera coordinate system may be acoordinate system of the left camera or a coordinate system of the rightcamera. In other words, for each pixel in the depth image, the processor210 and/or the coordinate determination unit 322 may take its coordinatein the depth image and determine and/or calculate the correspondingobject surface point's coordinate in the camera's coordinate system.

As described in step 510, the position (or image coordinate) of a pixelin the depth image may correspond to the position (or image coordinate)of a pixel in the first original image, and the first original image maybe any one of the two original images. Merely for demonstrationpurposes, the present invention may be described in detail bydesignating the original image taken by the left camera as the firstoriginal image.

In some embodiments, when the first original image is the original imagetaken by the left camera, the camera coordinate system may be thecoordinate system of the left camera (e.g., as illustrated in FIG. 6 ).In the camera coordinate system XC-YC-ZC, the origin is an opticalcenter of the left camera; the XC axis and YC axis of the cameracoordinate system are parallel to the XI axis and YI axis of theoriginal image taken by the left camera, respectively; the ZC axis ofthe camera coordinate system is an optical axis of the left camera.Herein, each pixel in the depth image may have a three-dimensionalcoordinate (px,py,pz) in the camera coordinate system satisfyingEquation (1), which may be expressed as:

$\begin{matrix}\begin{Bmatrix}{{px} = {b*{( {i - u} )/d}}} \\{{py} = {b*{( {j - v} )/d}}} \\{{pz} = {b*{f/d}}}\end{Bmatrix} & {{Equation}(1)}\end{matrix}$wherein, b is a length of the baseline distance of the binocular camera;i is a horizontal coordinate (e.g., the X_(I) coordinate) of the pixel;j is a vertical coordinate (e.g., the Y_(I) coordinate) of the pixel; uis a horizontal coordinate of a center pixel (e.g., pixel 630) of thedepth image; v is a vertical coordinate of the center pixel of the depthimage; d is a gray value of the pixel; and f is a focal length of theleft camera.

(b2) According to the three-dimensional coordinate of each pixel in thecamera coordinate system, the processor 210, or the coordinatedetermination unit 322, may determine a three-dimensional coordinate ofthe actual position corresponding to each pixel under the targetcoordinate system, i.e., for each pixel in the depth image (thus foreach pixel in the first original image as well), the processor 210and/or the coordinate determination unit 322 may determine the actualposition of the corresponding point on the one or more objects in thetarget scene, and determine the coordinate of the point in the currenttarget coordinate (e.g., the target coordinate, and/or an actualcoordinate system to be used for later procedures that measures thelocation of the one or more object).

In some embodiments, when the first original image is the original imagetaken by the left camera, a reference point (a projection of the opticalcenter of the left camera on the ground alone a vertical line) may beset as an origin (e.g., Ow) of the target coordinate system, the groundmay be taken as an X_(w)Z_(w) plane, a vertical line from the opticalcenter of the left camera to the ground may be set as an Y_(w) axis, anda projection of the optical axis of the left camera on the ground may beset as the Z_(w) axis.

The processor 210, or the coordinate determination unit 322, maydetermine a three-dimensional coordinate of the actual positioncorresponding to each pixel under the target coordinate system accordingto the three-dimensional coordinate of each pixel in the cameracoordinate system determined in step (b1). The three-dimensionalcoordinate (pxw,pyw,pzw) under the target coordinate system may satisfyEquation (2), which may be expressed as:

$\begin{matrix}\begin{Bmatrix}{{pxw} = {px}} \\{{pyw} = {{\cos\theta*{py}} - {\sin\theta*{pz}} + h}} \\{{pzw} = {{{- \sin}\theta*{py}} + {\cos\theta*{pz}}}}\end{Bmatrix} & {{Equation}(2)}\end{matrix}$wherein, θ is an installation pitch angle of a binocular camera withunchangeable pitch angle; and h is an installation height (e.g., withrespect to the optical center and ground) of the binocular camera withunchangeable height. The installation pitch angle and/or theinstallation height may be the pitch angle and/or the height of thebinocular camera (with unchangeable pitch angle and/or height) set by aninstaller of the binocular camera. However, for a binocular camera withchangeable pitch angle and/or height, θ and/or h may be a pitch angleand/or height (e.g., as illustrated in FIG. 6 ) of the binocular camerawhen the two original images are captured.

In some embodiments, as the ground is taken as the X_(w)Z_(w) planeunder the target coordinate system, the aforementioned pyw may beconsidered as a height (e.g., h) of the optical center of the binocularcamera with respect to the ground.

As described above, starting from two original images shot by abinocular camera, the methods and systems in the present disclosure maytransform the original images into a gray scale depth image, which isfurther used to determine objects' position in the target coordinatesystem (i.e., the target coordinate, also the target space and viewingangle). Next, the methods and systems in the present disclosure mayfurther identify target objects in the target space through the targetimage.

Step 530: the processor 210, or the marking image unit 323, may sift out(e.g., select and/or identify) first target pixels from the depth imageand generate a marking image (or mask) according to a position (or imagecoordinate) distribution of the first target pixels in the depth image.The three-dimensional coordinates of actual positions corresponding tothe first target pixels under the target coordinate system (or bereferred to as word coordinates of the first target pixels) may bewithin an identification range (preset range for identification). Themarking image may include a plurality of second target pixelscorresponding to the first target pixels. Gray values of the secondtarget pixels in the marking image may be a first gray value, grayvalues of other pixels in the marking image may be a second gray value.For example, the second target pixels, of which the position (or imagecoordinate) in the marking image may be the same as the position (orimage coordinate) of the first target pixels in the depth image, mayhave a gray value as the first gray value. Step 530 may be performed toachieve step 430 of process 400.

In some embodiments, the identification range may be a three-dimensionalcoordinate range within which a target object in the target scene mayactually be under the target coordinate system.

When the target object is an object of a different type, theidentification range may be varied accordingly. For example, when thetarget is a stand-up person (generally be identified by performing aface recognition on the stand-up person in the art), since a heightdistribution range of the face of the stand-up person may be between 1.3meters and 2.0 meters, a three-dimensional coordinate range of an actualposition of the face of the stand-up person in the target scene may be athree-dimensional coordinate range with a pyw between 1.3 and 2.0 underthe target coordinate system. As another example, when the target objectis a desktop of a desk, since a height distribution range of a desktopof the desk is between 0.5 meter and 1.2 meters, a three-dimensionalcoordinate range of an actual position of the desktop of the desk in thetarget scene may be a three-dimensional coordinate range with a pywbetween 0.5 and 1.2 (e.g., in the unit of meter) in thethree-dimensional coordinate.

In some embodiments, the processor 210, or the marking image unit 323,may sift out (e.g., select and/or identify) the first target pixels fromthe depth image. The sifting may include a four-step process describedas following:

(c1) The processor 210 may determine at least one interferent in thetarget scene (or disrupting pixels in the depth image) and determine athree-dimensional coordinate (or be referred to as a second targetcoordinate) of the at least one interferent (or each of the disruptingpixels) under the target coordinate system.

For example, when the target is a stand-up person, relatively highobjects such as a wall in the target scene may interfere with thelocating of the stand-up person according to the height distribution offace of the stand-up person. Therefore, it may be needed to locate atleast one interferent that may interfere with the locating of thestand-up person so as to avoid the interference. In some embodiments, aprocess for determining the at least one interferent in the target sceneand determining the three-dimensional coordinate of the at least oneinterferent under the target coordinate system may include operations asfollowing:

The processor 210, or the marking image unit 323, may obtain twobackground original images of the same target scene without the stand-upperson captured by the binocular camera and determine (or generate) abackground depth image without the stand-up person according to the twobackground original images.

The processor 210, or the marking image unit 323, may determine athree-dimensional coordinate of an actual position corresponding to eachpixel of the background depth image under the target coordinate systemthrough the process described in step 520.

The processor 210, or the marking image unit 323, may refer to theheight distribution range of the face of the stand-up person anddetermine at least one disrupting pixel in the background depth image.An object at an actual position corresponding to the at least onedisrupting pixel may be identified as the at least one interferent. Theprocessor 210, or the marking image unit 323, may also determine athree-dimensional coordinate of the at least one interferent under thetarget coordinate system. The three-dimensional coordinate of the actualposition corresponding to the at least one disrupting pixel under thetarget coordinate system may have a YW coordinate pywl within a heightrange of the stand-up person. For example, the three-dimensionalcoordinate of the interferent may satisfy 1.3<pywl<2.0 (e.g., in theunit of meter).

(c2) The processor 210, or the marking image unit 323, may determine aninterference range in the target scene (e.g., target scene 160 in FIG. 1) according to the three-dimensional coordinate(s) (second targetcoordinates) of the at least one interferent (or disrupting pixels)under the target coordinate system.

In the aforementioned example, optionally, a process for determining theinterference range may include:

When the three-dimensional coordinate of the at least one interferentsatisfies 1.3<pywl<2.0, the processor 210, or the marking image unit323, may set an XW coordinate of the three-dimensional coordinate as ahorizontal coordinate (e.g., XI coordinate) of a corresponding pixel inthe background marking image, and set a ZW coordinate of thethree-dimensional coordinate as a vertical coordinate (e.g., YIcoordinate) of a corresponding pixel in the background marking image,thereby the position (or image coordinate) of the at least oneinterferent in the background marking image may be determined. Fordemonstration purposes, FIG. 7 illustrates an exemplary backgroundmarking image. At least one pixel of the at least one interferent in thebackground marking image may be set to have a gray value of 255 or anyother gray value approximate to a gray value of white. Other pixels ofthe background marking image may be set to have a gray value of 0 or anyother gray value approximate to a gray value of black. Thereby thebackground marking image illustrated in FIG. 7 may include at least onewhite pixel indicating the position (or image coordinate) of the atleast one interferent in the background marking image.

It may be noted that, the background marking image may also take anyother proper forms or use any other proper colors (or color system) todistinguish the interferent(s) and other elements of the target scene.

The processor 210, or the marking image unit 323, may then determine aninterference range according to the background marking image. Forexample, the processor 210 may mark three-dimensional coordinates ofactual positions corresponding to some or all of the white pixels in thebackground marking image as the interference range. As another example,the processor 210, or the marking image unit 323, may draw (ordetermine) a polygonal chain surrounding, above, or below (asillustrated in FIG. 7 ) a series of image regions with dense whitepixels in the background marking image, and determine a region in thetarget scene corresponding to an image region enclosed by, below, orabove the polygonal chain as an interference range. An exemplarypolygonal chain is illustrated in FIG. 7 .

(c3) The processor 210 may determine the identification range accordingto the interference range. The identification range may not overlap withthe interference range.

For example, after determining the interference range in step (c2), theprocessor 210, or the marking image unit 323, may determine theidentification range according to the height range of the stand-upperson and the interference range. For demonstration purposes, in thebackground marking image illustrated in FIG. 7 , the identificationrange may be a three-dimensional coordinate range includingthree-dimensional coordinates of actual positions corresponding topixels in a region below the polygonal chain satisfying 1.3<pyw<2.0.

(c4) The processor 210, or the marking image unit 323, may sift out(e.g., select and/or identify) pixels of which the corresponding actualpositions have three-dimensional coordinates under the target coordinatesystem (or be referred to as third target coordinates) in theidentification range in the depth image, which may be designated asfirst target pixels.

In some embodiments, the processor 210, or the marking image unit 323,may generate a marking image (or mask) according to a position (or imagecoordinate) distribution of the first target pixels in the depth image,through a process described as following:

For example, the processor 210, or the marking image unit 323, may setsecond target pixels of the marking image to be generated, whosepositions (or coordinates) in the marking image is going to be the sameas that of the first target pixels in the depth image, to have grayvalues of a first gray value (or first gray values). The processor 210,or the marking image unit 323, may also set other pixels of the markingimage to be generated to have gray values of a second gray value (orsecond gray values). A first gray value and a second gray value may besubstantially different, so that the second target pixels may be clearlydistinguished from the other pixels in the marking image to begenerated. In some embodiments, a first gray value may be or beapproximate to a gray value of white, such as 200; a second gray valuemay be or be approximate to a gray value of black, such as 0.

The processor 210, or the marking image unit 323, may generate themarking image according to the gray value of each pixel (the secondtarget pixels and the other pixels) for generating the marking image. Anexemplary marking image is illustrated in in FIG. 8 . In the markingimage, white (or almost-white) pixels are the second target pixels andblack (or almost-black) pixels are the other pixels.

Step 540: the processor 210, or the locating coordinate determinationunit 324, may determine at least one connected component in the markingimage. Any one of pixels in an arbitrary connected component may beadjacent to at least one of other pixels in the same connectedcomponent. Any pixel adjacent to any one of the pixels in the connectedcomponent having a gray value within a preset gray value range may be inthe connected component. The preset gray value range may include thefirst gray value(s) but not include the second gray value(s). Step 540and step 550 may be performed in sequence to achieve step 440 of process400.

In some embodiments, the processor 210, or the locating coordinatedetermination unit 324, may determine the at least one connectedcomponent in the marking image in a process described as following:

The processor 210, or the locating coordinate determination unit 324,may perform a denoising operation on the marking image to generate adenoised marking image.

The processor 210, or the locating coordinate determination unit 324,may determine the at least one connected component including pixels withgray values in the gray value range in the denoised marking image.

In some embodiments, the denoising operation performed by the processor210, or the locating coordinate determination unit 324, on the markingimage may include the following steps:

(d1) The processor 210, or the locating coordinate determination unit324, may traverse each pixel in the marking image and sift out (e.g.,select and/or identify) at least one first pixel having a gray value ofthe first gray value. For example, the first gray value may be assumedto be 200.

(d2) The processor 210, or the locating coordinate determination unit324, may perform following operations for each of the at least one firstpixel: upon determining that a pixel with a gray value (or be referredto as a rule-out gray value, e.g., the second gray value(s)) other thanthe first gray value(s) or a third gray value presents in a first presetpixel range having a center at each first pixel, the processor 210, orthe locating coordinate determination unit 324, may set the gray valueof each first pixel as the third gray value. The third gray value may beapproximate to a gray value of white but different from the rule-outgray value, and the third gray value may not be included in the presetgray value range. For example, the third gray value may be assumed to be199.

In some embodiments, assuming that a first pixel has a coordinate of (m,n) in the marking image, the first preset pixel range may be a rangesatisfying m−3<=x<=m+3 and n−3<=y<=n+3, wherein (x, y) may represent acoordinate of an arbitrary pixel in the first preset pixel range.

(d3) The processor 210, or the locating coordinate determination unit324, may traverse each pixel in the marking image again and sift out(e.g., select and/or identify) at least one second pixel having a grayvalue of the first gray value(s).

(d4) The processor 210, or the locating coordinate determination unit324, may perform the following operations for each of the at least onesecond pixel: the processor 210, or the locating coordinatedetermination unit 324, may sift out (e.g., select and/or identify) atleast one third pixel having a gray value other than the first grayvalue(s) from a second preset pixel range having a center at the secondpixel. The processor 210, or the locating coordinate determination unit324, may set a gray value of the at least one third pixel sifted out asa fourth gray value. The fourth gray value may be included in the presetgray value range. The fourth gray value may be or be approximate to agray value of white. For example, the fourth gray value may be assumedto be 255.

In some embodiments, assuming that the second pixel has a coordinate of(m1, n1) in the marking image, the second preset pixel range may be arange satisfying m1-3<=x1<=m1+3 and n1-3<=y1<=n1+3, wherein (x1, y1) mayrepresent a coordinate of an arbitrary pixel in the second preset pixelrange.

An exemplary denoised marking image obtained by denoising the markingimage through the aforementioned steps is illustrated in FIG. 9 . It maybe seen from FIG. 9 that, compared to FIG. 8 , the connected componentsillustrated in FIG. 9 is smoother than the connected componentillustrated in FIG. 8 . Small connected components in FIG. 8 that may benegligible is also removed in FIG. 9 . Therefore, by performing thedenoising operation, the connected component in the marking image may bemore accurate, and the position of the target object to be located maybe determined more accurately in the marking image.

Step 550: the processor 210, or the locating coordinate determinationunit 324, may sift out (e.g., select and/or identify) a target connectedcomponent with a number of pixels greater than or equal to a presetthreshold from the at least one connected component, and designate athree-dimensional coordinate (or be referred to as a fourth targetcoordinate) of an actual position corresponding to a center of thetarget connected component under the target coordinate system as thethree-dimensional coordinate (locating coordinate) of the target objectin the target scene. Step 540 and step 550 may be performed in sequenceto achieve step 440 of process 400.

In some embodiment, a plurality of target connected components may besifted out. Correspondingly, a plurality of target objects may bedetermined with a same number of three-dimensional coordinates.

In some embodiments, the target object may be a stand-up person. Theprocessor 210, or the locating coordinate determination unit 324, mayset the preset threshold (e.g., 50) according to the face of thestand-up person. Then the processor 210, or the locating coordinatedetermination unit 324, may determine the number of pixels included inthe at least one connected component using a technique in the art anddetermine a connected component with a number of pixels greater than orequal to the preset threshold (e.g., 50) as the target connectedcomponent.

In some embodiments, after the target connected component is sifted out,a pixel coordinates at a center of the target connected component may bea coordinate of the target object in the image coordinate system (e.g.,as illustrated in FIG. 6 ). Denoting the target connected component (orone of the target connected components) as a target connected componentA, a pixel coordinate (cx, cy) of a center of the target connectedcomponent A may satisfy the Equation (3), which may be expressed asfollowing:

$\begin{matrix}\begin{Bmatrix}{{cx} =} & {\sum\limits_{{p({s,q})} \in A}\frac{s}{N}} \\{{cy} =} & {\sum\limits_{{p({s,q})} \in A}\frac{q}{N}}\end{Bmatrix} & {{Equation}(3)}\end{matrix}$wherein, p(s, q) represents a coordinate of an arbitrary pixel in thetarget connected component A, and N is the number of pixels in thetarget connected component A.

After the coordinate of the center of the target connected component isobtained through the aforementioned process, a three-dimensionalcoordinate under the target coordinate system of an actual positioncorresponding to the center of the target connected component may beobtained (e.g., by the locating coordinate determination unit 324 and/orthe coordinate determination unit 322) using the process described instep 520 for determining a three-dimensional coordinate under the targetcoordinate system of an actual position corresponding to a pixel. Athree-dimensional coordinate of the target object in the target scenemay then be obtained. Therefore, the actual position of the targetobject in the target scene may be determined, resulting in an accuratelocating of the target object, which may enable performing subsequentoperations upon the target object.

For example, the target object may be a stand-up person. After thethree-coordinate of the stand-up person in the target scene isdetermined, information such as a name of the stand-up person may beobtained (e.g., by the locating device 140) according to a seating chartand the three-dimensional coordinate. Follow-ups such as shooting inclose-up or communicating with the stand-up person may then be performedsubsequently.

FIG. 6 is a schematic diagram illustrating exemplary relationships amongan image coordinate system, a camera coordinate system (sensorcoordinate system), a target coordinate system according to someembodiments of the present disclosure. The relationships may be used forlocating a target object in a target scene captured by an imagecapturing mechanism (e.g., the image capturing mechanism 110) includinga first camera 610 (first image sensor) and a second camera 620 (secondimage sensor). Optical centers of the first camera 610 (e.g., a leftcamera) and the second camera 620 (e.g., a right camera) may define alinear segment, which may be referred to as a baseline of the imagecapturing mechanism (e.g., a binocular camera). The baseline may beparallel with a horizontal plane (or the ground).

An image coordinate system may be a two-dimensional coordinate systemdescribing a position of a pixel in an image such as an original image,a depth image, or a marking image. In the present disclosure, anoriginal pixel in an original image (e.g., first original image taken bythe first camera 610), a first corresponding pixel (e.g., a first targetpixel) in a depth image generated according to the original pixel, and asecond corresponding pixel (e.g., a second target pixel) in a markingimage generated according to the first corresponding pixel, may allcorrespond to a same point in the target scene. So the first originalimage, the depth image, and the marking image may all use a same imagecoordinate system as illustrated in FIG. 6 . For example, for arectangular image, the original (O_(I)) of the image coordinate systemmay be one of vertices of the image (e.g., the bottom left vertex). AnX_(I) axis and a Y_(I) axis of the image coordinate system may beparallel with adjacent sides of the image. In some embodiments, theX_(I) axis may be parallel with the ground.

A camera coordinate system (sensor coordinate system) may be athree-dimensional coordinate describing actual positions (or points)corresponding to pixels of an image with respect to a camera (e.g., thefirst camera 610) taking the image. As the depth image and the markingimage may share a same image coordinate system with the first originalimage, a camera coordinate system of the left camera 610 may alsocorrelate with the image coordinate system of the marking image or thedepth image.

In the present disclosure, an original (O_(C)) of the camera coordinatesystem may be an optical center of the first camera 610. The originalO_(C) may correspond to a center point 630 of the image (the firstoriginal image, the depth image or the marking image). An X_(C) axis anda Y_(C) axis of the camera coordinate system may be parallel with theX_(I) axis and the Y_(I) axis of the image coordinate system of theimage. For example, the XC axis may be parallel with the ground. An ZCaxis may be the optical axis of the first camera 610. An angle definedby a horizontal plane and the ZC axis (or the optical axis) may be thepitch angle θ involved in the Equation (2).

A target coordinate system (e.g., a world coordinate system) may be athree-dimensional coordinate system describing actual positions (orpoints) corresponding to pixels by an image (e.g., the depth imageand/or the original images) with respect to a scene (e.g., the targetscene) showed by the image. An original (OW) of the target coordinatesystem may be set on the ground. In some embodiments, a projection pointof the optical center of the first camera 610 on the ground along avertical line may be set as the original OW; an XW axis of the targetcoordinate system may be parallel with the XC axis; a YW axis may beperpendicular to the ground, and a ZW axis may be a projection of theoptical axis of the first camera 610 (or the ZC axis) on the ground. Aheight between the optical center of the first camera 610 and the groundmay be the height h involved in the Equation (2).

Equation (1) may be adopted for converting an image coordinate under animage coordinate system to a corresponding camera coordinate under acorresponding camera coordinate system. Equation (2) may be adopted forconverting a camera coordinate under a camera coordinate system to acorresponding target coordinate under a target coordinate system. Acombined equation of Equation (1) and Equation (2) may be adopted forconverting an image coordinate to a corresponding target coordinatedirectly. However, it is to be understood that the one-step coordinateconversion from an image coordinate to a target coordinate using thecombined equation may also be considered as first converting the imagecoordinate to a corresponding camera coordinate, then converting thecamera coordinate to the target coordinate.

FIG. 7 is a schematic diagram illustrating an exemplary backgroundmarking image according to some embodiments of the present disclosure.The white pixels in the background marking image are disrupting pixelsrepresenting interferents in the target region. The white polygonalchain in the background marking image differentiate an inference range(above the polygonal chain) from the rest part of the marking image.

FIG. 8 is a schematic diagram illustrating an exemplary marking imageaccording to some embodiments of the present disclosure. The whitepixels in the marking image are second targeting pixels representingpotential target objects. A plurality of connected components may beidentified in the FIG. 8 .

FIG. 9 is a schematic diagram illustrating an exemplary marking imageobtained by denoising the marking image illustrated in FIG. 8 accordingto some embodiments of the present disclosure. Compared to FIG. 8 , theconnected components illustrated in FIG. 9 is smoother than theconnected component illustrated in FIG. 8 . Small connected componentsin FIG. 8 that may be negligible is also removed in FIG. 9 .

Having thus described the basic concepts, it may be rather apparent tothose skilled in the art after reading this detailed disclosure that theforegoing detailed disclosure is intended to be presented by way ofexample only and is not limiting. Various alterations, improvements, andmodifications may occur and are intended to those skilled in the art,though not expressly stated herein. These alterations, improvements, andmodifications are intended to be suggested by this disclosure, and arewithin the spirit and scope of the exemplary embodiments of thisdisclosure.

Moreover, certain terminology has been used to describe embodiments ofthe present disclosure. For example, the terms “one embodiment,” “anembodiment,” and/or “some embodiments” mean that a particular feature,structure or characteristic described in connection with the embodimentis included in at least one embodiment of the present disclosure.Therefore, it is emphasized and should be appreciated that two or morereferences to “an embodiment” or “one embodiment” or “an alternativeembodiment” in various portions of this specification are notnecessarily all referring to the same embodiment. Furthermore, theparticular features, structures or characteristics may be combined assuitable in one or more embodiments of the present disclosure.

Further, it will be appreciated by one skilled in the art, aspects ofthe present disclosure may be illustrated and described herein in any ofa number of patentable classes or context including any new and usefulprocess, machine, manufacture, or composition of matter, or any new anduseful improvement thereof. Accordingly, aspects of the presentdisclosure may be implemented entirely hardware, entirely software(including firmware, resident software, micro-code) or combiningsoftware and hardware implementation that may all generally be referredto herein as a “unit,” “module,” or “system.” Furthermore, aspects ofthe present disclosure may take the form of a computer program productembodied in one or more computer readable media having computer readableprogram code embodied thereon.

A computer readable signal medium may include a propagated data signalwith computer readable program code embodied therein, for example, inbaseband or as part of a carrier wave. Such a propagated signal may takeany of a variety of forms, including electro-magnetic, optical, or thelike, or any suitable combination thereof. A computer readable signalmedium may be any computer readable medium that is not a computerreadable storage medium and that may communicate, propagate, ortransport a program for use by or in connection with an instructionexecution system, apparatus, or device. Program code embodied on acomputer readable signal medium may be transmitted using any appropriatemedium, including wireless, wireline, optical fiber cable, RF, or thelike, or any suitable combination of the foregoing.

Computer program code for carrying out operations for aspects of thepresent disclosure may be written in any combination of one or moreprogramming languages, including an object oriented programming languagesuch as Java, Scala, Smalltalk, Eiffel, JADE, Emerald, C++, C#, VB. NET,Python or the like, conventional procedural programming languages, suchas the “C” programming language, Visual Basic, Fortran 2103, Perl, COBOL2102, PHP, ABAP, dynamic programming languages such as Python, Ruby andGroovy, or other programming languages. The program code may executeentirely on the user's computer, partly on the user's computer, as astand-alone software package, partly on the user's computer and partlyon a remote computer or entirely on the remote computer or server. Inthe latter scenario, the remote computer may be connected to the user'scomputer through any type of network, including a local area network(LAN) or a wide area network (WAN), or the connection may be made to anexternal computer (for example, through the Internet using an InternetService Provider) or in a cloud computing environment or offered as aservice such as a Software as a Service (SaaS).

Furthermore, the recited order of processing elements or sequences, orthe use of numbers, letters, or other designations therefore, is notintended to limit the claimed processes and methods to any order exceptas may be specified in the claims. Although the above disclosurediscusses through various examples what is currently considered to be avariety of useful embodiments of the disclosure, it is to be understoodthat such detail is solely for that purpose, and that the appendedclaims are not limited to the disclosed embodiments, but, on thecontrary, are intended to cover modifications and equivalentarrangements that are within the spirit and scope of the disclosedembodiments. For example, although the implementation of variouscomponents described above may be embodied in a hardware device, it mayalso be implemented as a software only solution, for example, aninstallation on an existing server or mobile device.

Similarly, it should be appreciated that in the foregoing description ofembodiments of the present disclosure, various features are sometimesgrouped together in a single embodiment, figure, or description thereoffor the purpose of streamlining the disclosure aiding in theunderstanding of one or more of the various inventive embodiments. Thismethod of disclosure, however, is not to be interpreted as reflecting anintention that the claimed object matter requires more features than areexpressly recited in each claim. Rather, inventive embodiments lie inless than all features of a single foregoing disclosed embodiment.

In some embodiments, the numbers expressing quantities or propertiesused to describe and claim certain embodiments of the application are tobe understood as being modified in some instances by the term “about,”“approximate,” or “substantially.” For example, “about,” “approximate,”or “substantially” may indicate ±20% variation of the value itdescribes, unless otherwise stated. Accordingly, in some embodiments,the numerical parameters set forth in the written description andattached claims are approximations that may vary depending upon thedesired properties sought to be obtained by a particular embodiment. Insome embodiments, the numerical parameters should be construed in lightof the number of reported significant digits and by applying ordinaryrounding techniques. Notwithstanding that the numerical ranges andparameters setting forth the broad scope of some embodiments of theapplication are approximations, the numerical values set forth in thespecific examples are reported as precisely as practicable.

Each of the patents, patent applications, publications of patentapplications, and other material, such as articles, books,specifications, publications, documents, things, and/or the like,referenced herein is hereby incorporated herein by this reference in itsentirety for all purposes, excepting any prosecution file historyassociated with same, any of same that is inconsistent with or inconflict with the present document, or any of same that may have alimiting affect as to the broadest scope of the claims now or laterassociated with the present document. By way of example, should there beany inconsistency or conflict between the description, definition,and/or the use of a term associated with any of the incorporatedmaterial and that associated with the present document, the description,definition, and/or the use of the term in the present document shallprevail.

In closing, it is to be understood that the embodiments of theapplication disclosed herein are illustrative of the principles of theembodiments of the application. Other modifications that may be employedmay be within the scope of the application. Thus, by way of example, butnot of limitation, alternative configurations of the embodiments of theapplication may be utilized in accordance with the teachings herein.Accordingly, embodiments of the present application are not limited tothat precisely as shown and described.

What is claimed is:
 1. A locating system for locating a target object ina target scene, comprising at least one locating device, wherein duringoperation, the at least one locating device is configured to: obtain adepth image of the target scene, the depth image including a pluralityof pixels; for each of the plurality of pixels of the depth image,determine a first target coordinate under a target coordinate system;generate a marking image based on the depth image and the first targetcoordinates of the plurality of pixels in the depth image, wherein themarking image represents potential target objects in the depth image;determine at least one connected component in the marking image under animage coordinate system; and determine a locating coordinate of thetarget object under the target coordinate system based on the at leastone connected component.
 2. The locating system of claim 1, to generatethe depth image, the at least one locating device is configured to:receive first electronic signals including a first image of the targetscene taken by a first image sensor; receive second electronic signalsincluding a second image of the target scene taken by a second imagesensor; and for each pixel in the first image: determine a horizontalparallax between the pixel of the first image and a corresponding pixelof the second image; and according to the horizontal parallax, assign agray value to a corresponding pixel of the depth image.
 3. The locatingsystem of claim 2, further comprising: the first image sensor configuredto obtain the first image of the target scene; and the second imagesensor at a predetermined distance from the first image sensor,configured to obtain the second image of the target scene simultaneouslywith the first image sensor, wherein the first image includes aplurality of pixels one-to-one corresponding to a plurality of pixels inthe second image.
 4. The locating system of claim 3, wherein the firstimage sensor is at least part of a first camera in a binocular camera;and the second image sensor is at least part of a second camera in thebinocular camera.
 5. The locating system of claim 2, wherein for each ofthe plurality of pixels in the depth image, to determine the firsttarget coordinate, the at least one locating device is configured to:determine a sensor coordinate of the pixel under a sensor coordinatesystem with respect to the first image sensor according to a first imagecoordinate and the gray value of the pixel; and determine the firsttarget coordinate according to the sensor coordinate of the pixel. 6.The locating system of claim 2, further comprising a controller,wherein: the locating device is further configured to transmit thirdelectronic signals including the locating coordinate to the controller;and the controller, upon receiving the third electronic signals,transmits a control signal to at least one of the first image sensor orthe second image sensor, causing the at least one of the first imagesensor or the second image sensor to be focused or zoomed in towards thelocating coordinate.
 7. The locating system of claim 1, wherein togenerate the marking image according to the depth image and theplurality of first target coordinates, the at least one locating deviceis configured to: determine disrupting pixels in the depth image, thedisrupting pixels indicating one or more interferents presented in thetarget scene; for each of the disrupting pixels, determine a secondtarget coordinate; determine an interference range in the target sceneaccording to the second target coordinates and a target region in thetarget scene where the target object is predicted to appear; determinean identification range in the target scene according to theinterference range and the target region by excluding disrupting pixelsfrom the target scene, wherein the identification range does not overlapwith the interference range; identify first target pixels having thirdtarget coordinates within the identification range in the depth image;and generate the marking image according to the first target pixels. 8.The locating system of claim 7, wherein: the marking image includessecond target pixels corresponding to the first target pixels; thesecond target pixels have first gray values; and other pixels in themarking image have second gray values.
 9. The locating system of claim1, wherein to determine the locating coordinate of the target objectbased on the at least one connected component, the at least one locatingdevice is configured to: determine a target connected component from theat least one connected component; determine a locating point in themarking image according to the target connected component; and determinethe locating coordinate according to a second image coordinate of thelocating point.
 10. The locating system of claim 9, wherein to determinethe target connected component from the at least one connectedcomponent, the at least one locating device is configured to: identify aconnected component having a number of pixels greater than or equal to apreset threshold from the at least one connected component as the targetconnected component.
 11. A method for locating a target object in atarget scene, comprising: obtaining, by a locating device, a depth imageof the target scene, the depth image including a plurality of pixels;for each of the plurality of pixels of the depth image, determining, bythe locating device, a first target coordinate under a target coordinatesystem; generating, by the locating device, a marking image according tothe depth image and the first target coordinates of the plurality ofpixels in the depth image, wherein the marking image representspotential target objects in the depth image; determining at least oneconnected component in the marking image under an image coordinatesystem; and determining, by the locating device, a locating coordinateof the target object under the target coordinate system based on the atleast one connected component.
 12. The method of claim 11, wherein thegenerating the depth image comprises: receiving first electronic signalsincluding a first image of the target scene taken by a first imagesensor; receiving second electronic signals including a second image ofthe target scene taken by a second image sensor; and for each pixel inthe first image: determining a horizontal parallax between the pixel ofthe first image and a corresponding pixel of the second image; andaccording to the horizontal parallax, assigning a gray value to acorresponding pixel of the depth image.
 13. The method of claim 12,further comprising: obtaining, by the first image sensor, the firstimage of the target scene; and obtaining, by the second image sensor ata predetermined distance from the first image sensor, the second imageof the target scene simultaneously with the first image sensor, whereinthe first image includes a plurality of pixels one-to-one correspondingto a plurality of pixels in the second image.
 14. The method of claim12, wherein for each of the plurality of pixels in the depth image, thedetermining the first target coordinate comprises: determining a sensorcoordinate of the pixel under a sensor coordinate system with respect tothe first image sensor according to a first image coordinate and thegray value of the pixel; and determining the first target coordinateaccording to the sensor coordinate of the pixel.
 15. The method of claim12, further comprising: transmitting, by the locating device, thirdelectronic signals including the locating coordinate to the controller;and transmitting, by a controller upon receiving the third electronicsignals, a control signal to at least one of the first image sensor orthe second image sensor, causing the at least one of the first imagesensor or the second image sensor to be focused or zoomed in towards thelocating coordinate.
 16. The method of claim 11, wherein the generatingthe marking image according to the depth image and the plurality offirst target coordinates comprises: determining disrupting pixels in thedepth image, the disrupting pixels indicating one or more interferentspresented in the target scene; for each of the disrupting pixels,determining a second target coordinate; determining an interferencerange in the target scene according to the second target coordinates anda target region in the target scene where the target object is predictedto appear; determining an identification range in the target sceneaccording to the interference range and the target region by excludingdisrupting pixels from the target scene, wherein the identificationrange does not overlap with the interference range; identifying firsttarget pixels having third target coordinates within the identificationrange in the depth image; and generating the marking image according tothe first target pixels.
 17. The method of claim 16, wherein: themarking image includes second target pixels corresponding to the firsttarget pixels; the second target pixels have first gray values; andother pixels in the marking image have second gray values.
 18. Themethod of claim 11, wherein the determining the locating coordinate ofthe target object based on the at least one connected componentcomprises: identifying a connected component having a number of pixelsgreater than or equal to a preset threshold from the at least oneconnected component as a target connected component; determining alocating point in the marking image according to the target connectedcomponent; and determining the locating coordinate according to a secondimage coordinate of the locating point.
 19. A non-transitory computerreadable medium, storing instructions, the instructions when executed bya processor, causing the processor to execute operations comprising:obtaining a depth image of the target scene, the depth image including aplurality of pixels; for each of the plurality of pixels of the depthimage, determining a first target coordinate under a target coordinatesystem; generating a marking image according to the depth image and thefirst target coordinates of the plurality of pixels in the depth image,wherein the marking image represents potential target objects in thedepth image; determining at least one connected component in the markingimage under an image coordinate system; and determining, by the locatingdevice, a locating coordinate of the target object under the targetcoordinate system based on the at least one connected component.
 20. Thelocating system of claim 7, wherein to determine the disrupting pixelsin the depth image, the at least one locating device is furtherconfigured to: obtain a background depth image of the same target scenewithout the target object; for each of a plurality of pixels of thebackground depth image, determine a forth target coordinate under thetarget coordinate system; determine, in the background depth image, thedisrupting pixels from the plurality of pixels of the background depthimage based on a height distribution range of the target object underthe target coordinate system; and determine corresponding disruptingpixels in the depth image based on the disrupting pixels in thebackground depth image.